You can translate your example in Scala like so:

```
import concurrent.{Await, Future, future}
import concurrent.ExecutionContext.Implicits.global
import concurrent.duration.Duration
object Main extends App {
val fac: Int => Int = {
case 0 => 1
case n => n * fac(n-1)
}
val ack: (Int, Int) => Int = {
case (0, n) => n + 1
case (m, 0) => ack (m-1, 1)
case (m, n) => ack (m-1, ack(m, n-1))
}
val fib: Int => Int = {
case 0 => 0
case 1 => 1
case n => fib(n-1) + fib(n-2)
}
val fa = future { ack(3, 10) }
val fb = future { fac(42) }
val fc = future { fib(35) }
val x = for (((a, b), c) <- fa zip fb zip fc) yield (a + b + c)
val result = Await.result(x, Duration.Inf) //awaiting synchronously after the result
println(s"Value is: $result")
}
```

The `future { fib(3, 10) }`

bit will create an asynchronous computation which will run on a different execution thread and will return a `Future`

object. You can then compose all your futures into one big future which will provide the list of all the results, using `Future.sequence`

.

We can map the result of this latter future into the sum of the results, thus obtaining the final value.

With this final future we can do several things. We can compose it further or we can attach callbacks on it or we can wait synchronously for a specified duration of time. In my example I am waiting in a synchronous fashion after the result for an infinite period of time.

`ghc -O2 -threaded Par.hs --make -fforce-recomp`

– jaybee Apr 2 '13 at 18:41